Cardiovascular and catecholamine responses to static exercise in partially curarized humans

Neural control of the circulation was evaluated during static exercise in 19 subjects by the determination of heart rate (HR), mean arterial pressure (MAP), cardiac output (CO) and plasma catecholamines. Influence from central command was evaluated during contractions with weakened muscles following partial curarization and reflex influence from metaboreceptors was assessed by post-exercise muscle ischaemia. Static handgrip increased HR and more so MAP and CO and MAP remained elevated during post-exercise muscle ischaemia. With partial curarization plasma catecholamines were also increased (P<0.05). Two-leg extension increased all variables and during post-exercise muscle ischaemia elevations of HR, MAP and CO were maintained (P<0.05). With partial curarization HR, MAP and plasma noradrenaline were even greater during the contraction. With the involvement of both legs during static exercise, reflex influence from the muscles elevated blood pressure by way of HR and CO and the importance of central command was detectable for HR and MAP as plasma catecholamines became elevated. However, the results indicate a separation between a central command influence on HR and CO related to an increase in plasma catecholamines during a handgrip, while the reflex influence on blood pressure was directed towards total peripheral resistance.     

Skeletal muscle perfusion in electrically induced dynamic exercise in humans

Leg blood flow, blood pressure and metabolic responses were evaluated in six men during incremental one-legged dynamic knee extension exercise tests (no load exercise - 40 W); one performed with voluntary contractions (VOL) and one with electrically induced contractions (EMS). Pulmonary oxygen uptake was the same in both exercise modes, but the ventilatory coefficient was 2–5 L per L O₂ higher in EMS than VOL (P < 0.05). Heart rate and mean arterial pressure were slightly higher with EMS than VOL at all exercise intensities reaching 138 (EMS) and 126 bpm (VOL), as well as 148 (EMS) and 137 mmHg (VOL) at 40 W, respectively (P < 0.05). Leg blood flow, oxygen uptake and conductance were similar in the two exercise modes. At 40 W, mean muscle blood flow was close to 200 (range: 165–220) mL 100 g^-1 min^-1, mean peak muscle oxygen uptake reached 230 mL kg^-1 min^-1, and mean conductance became as high as around 45 mL min^-1 mmHg^-1, and normalized for muscle size and arterial pressure it approached 100 mL min^-1 100 g^-1 100 mmHg^-1. Lactate and ammonia efflux from the leg were higher with EMS than with VOL and the difference became larger with increasing exercise intensity (P < 0.05). Muscle glucose uptake was the same in each exercise mode. Femoral venous K⁺ concentration increased with exercise intensity and was higher with EMS than with VOL, reaching 5.1 (EMS) and 4.7 mmol L^-1 (VOL) at 40 W (P < 0.05). The study demonstrates that electrically induced dynamic exercise is associated with a marked cardiovascular response similar to voluntarily performed exercise and a more pronounced activation of the anaerobic metabolism of the muscle. Furthermore, as the electrically activated muscle group is well defined, the present results confirm that peak muscle blood flow can reach 200–250 mL 100 g^-1 min^-1.     

Cardiovascular and endocrine responses to haemorrhage in the pig

Heart rate (HR), mean arterial pressure (MAP), indices of sympathetic and parasympathetic activity (plasma concentrations of adrenaline, noradrenaline and pancreatic polypeptide, PP), vasopressin (VP) and aldosterone (ALDO) were measured in six pigs during continuous bleeding resulting in hypovolaemic shock, from which five survived. Three stages of haemorrhage could be defined. Stage I. Resting MAP was 85 ± 6 mmHg and increased to 96 ± 5 mmHg with a blood loss of 275 (range 250–300) (10 (9–12)% of the estimated blood volume) concomitant with an increase in HR from 105 ± 5 to 113 ± 6 beats min^-1 (P < 0.05). Stage II. After a blood loss of 375 (300–500) ml (15 (13–16)%) MAP fell to 62 ± 9 mmHg and HR to 95 ± 5 beats min^-1 (P < 0.05). Stage III. A blood loss of 1113 (825–1450) ml (44 (30–52)%) resulted in a MAP of 50 ± 4 mmHg and an increase in HR to 206 ± 3 beats min^-1 (P < 0.05). Adrenaline increased from 0.3 ± 0.1 to 0.8 ± 0.3 (stage II) and 3.6 ± 1.1 nmol l^-1 (stage III) (P < 0.05); noradrenaline from 0.4 ± 0.1 to 1.5 ± 0.4 (stage II) and 5.9 ± 1.7 nmol l^-1 (stage III) (P < 0.05); PP from 6.2 ± 1.6 to 13.3 ± 2.3 (stage II) and 20.9 ± 7.8 pmol l^-1 (stage III) (P < 0.05). VP changed only marginally, but ALDO increased from 496 ± 54 to 623 ± 76 pmol l^-1 (stage III) (P < 0.05). The results suggest that a high HR and intense sympathetic activity is seen during severe haemorrhage in the pig while vagal slowing of the heart and moderate hypotension are prominent when bleeding amounts to approximately 15% of the estimated blood volume.     

Cardiovascular response to exercise in humans following acclimatization to extreme altitude

The purpose of this study was to assess the effects of acclimatization to extreme altitude on the cardiovascular system, using vagal and adrenergic blockade and acute restoration of normoxia during exercise to maximum with one and two legs. Fourteen climbers on an expedition to the Himalayas were studied at a lower base camp (5250 m) following 56–81 days at altitudes between 5250 and 8700 m. After acclimatization, peak heart rate (HR_peak), oxygen uptake (o_2k) and noradrenaline (NA) were similar during maximal one- and two-legged cycling, whereas peak plasma lactate was higher during the one-legged protocol. HR_peak (range 113–168 beats min“¹) was lowest when subjects returned from the higher camps. The degree of partial restoration of HR_peak to more normal values within seconds of 60% 0₂ inhalation (range 5–35 beats min?^l HR_peak increase) was greatest in subjects with low HR_peak. HR responses to /?-l blockade increased as a function of HR_peak and the HR responses to atropine were the least in subjects with high HRpeak- These findings suggest that (a) the reduction in HR_peak is linked to the duration and severity of the hypoxaemia, (b) the degree of restoration of HR_peak with acute normoxia is dependent on the level of attenuation or down-regulation of cardiac sympathetic activation (SNA), (c) cardiac vagal drive is masked to a lesser extent in chronic hypoxia because of attenuated SNA and lower HR_peak values, and (d) the lower blood lactate levels at altitude is a function of muscle mass involvement rather than adrenergic activation, as normal peak values were reached during exercise with a small muscle mass.     

Splanchnic and renal vasoconstrictor and metabolic responses to neuropeptide Y in resting and exercising man

The local clearance of neuropeptide Y (NPY) and whether NPY influences splanchnic and renal metabolism in man have not been investigated previously. The influence of NPY on splanchnic and renal blood flows at physiologically elevated levels has also not been investigated. The effects of a 40-min constant NPY infusion (3 pmol kg^-1 min^-1) at rest and during 130 min of exercise (50% of Vo_2max) were studied in six healthy subjects and compared with resting and exercising subjects receiving no NPY. Blood samples were drawn from arterial, hepatic and renal vein catheters for the determination of blood flows (indicators: cardiogreen and paraaminohippuric acid [PAH]), NPY, catecholamines, glucose, lactate and glycerol. NPY infusion was accompanied by: (1) significant fractional extraction of NPY-like immunoreactivity (NPY-Li) by splanchnic tissues at rest (58±5%) and during exercise (53±6%), while no arterial–venous differences could be detected across the kidney; (2) a reduction in splanchnic and renal blood flows of up to 18 and 13% respectively (P < 0.01–0.001) at rest without any additional changes during exercise; and (3) metabolic changes as reflected in: (a) a more marked fall in arterial glucose during exercise compared to the reference group (P < 0.05); (b) a 35% lower splanchnic glucose release (P < 0.01) during exercise due to diminished glycogenolysis (P < 0.01); and (c) a lower arterial lactate level (18%P < 0.05) together with unchanged splanchnic lactate uptake during exercise, suggesting reduced lactate production by extrahepatic tissues. The disappearance of plasma NPY-Li after the infusions was biphasic with two similar half-lives at rest (4 and 39 min) and during exercise (3 and 43 min).     

Thoracic impedance and pulmonary atrial natriuretic peptide during head-up tilt induced hypovolaemic shock in humans

Head up and down tilts were used for manipulating the central blood volume in eight volunteers. During head-up tilt thoracic electrical impedance (TI) increased from 36.7 (33.9–52.1) ohm (mean and range) to 41.9 (36.9–59.2) ohm, heart rate from 60 (49–72) to 80 (65–90) beats min^-1 (P < 0.05) and decreased again to 57 (48–67) beats min^-1 accompanying a fall in mean arterial pressure from 86 (76–97) to 54 (41–79) mmHg and in cardiac output from 9.2 (5.9–12.1) to 6.9 (3.4–8.8) 1 min-¹ (n= 7, P < 0.07). Central venous pressure did not change significantly. Pulmonary arterial mean, 6 (3–12) mmHg, and wedge pressures, 4 (1–9) mmHg, decreased to 4 (1–11) and 1 (0–7) mmHg, respectively, and mixed, 78 (77–79%), and central venous oxygen saturations, 72 (71–73)%, fell to 62 (46–75) and 54 (44–58)%, respectively (P < 0.05). Atrial natriuretic peptide (ANP) was determined from blood of the superior vena cava and pulmonary and brachial arteries. Pulmonary artery ANP, 18.4 (7.5–30.7) pmol l^-1, was higher than in vena cava, 13.3 (5.2–20.9) pmol 1^_1 (P < 0.05). At the time of presyncope, pulmonary artery ANP decreased from 20.8 (37.4–10.1) to 13.7 (19.7-5.7) pmol l^-1, in vena cava from 13.8 (23.1–7.1) to 10.2 (17.9-6.7) pmol l^-‘ and in the brachial artery from 16.9 (34.1–5.2) to 11.3 (18.5-5.1) pmol l“¹ (P < 0.05). Head-down tilt did not affect the recorded variables significantly. Thoracic electrical impedance, pulmonary artery pressure and venous oxygen saturations were sensitive indices of the central blood volume as reflected in the release of atrial natriuretic peptide from the right side of the heart.     

Hemodynamic Reactivity to Laboratory Stressors in Healthy Subjects: Influence of Gender and Family History of Cardiovascular Diseases

Although laboratory stressor tests have been applied as a preliminary protocol in some cardiovascular studies, there is a lack of data comparing the pressor and chronotropic responses among the main stressor tests. Therefore, the aim of this study was to evaluate the variability in hemodynamic responsiveness to the main stressor tests, establish a hyperresponsiveness cutoff criterion and analyze the influence of gender and family history of cardiovascular diseases (CVDs) in healthy subjects. We examined hemodynamic responses to physical (cold pressor and handgrip tests) and mental (Stroop color-word test) stressors in 98 subjects (48 males and 50 females) without CVDs. All stressor tests resulted in increased blood pressure (BP) levels, which were lower and less dispersed in the handgrip test compared to the cold pressor test. Adopting the 75^th percentile as the cutoff in our data, we classified subjects exhibiting absolute pressor changes equal to or higher than 14, 24 and 36 mmHg in systolic and 9, 13 and 24 mmHg in diastolic BP during the handgrip, Stroop and cold pressor test, respectively, as hyperresponsives. Males exhibited greater (p<0.05) increases in systolic BP in the handgrip (11% vs. 8%) and cold pressor (25% vs. 21%) tests and in diastolic BP in the handgrip (12% vs. 7%) and Stroop (22% vs. 19%) tests than females. A positive association between family history of CVDs and pressor hyperreactivity to stressor tests was observed. We propose using the 75^th percentile of hemodynamic sample values as a cutoff criterion to classify individuals as pressor or chronotropic hyperreactives. We conclude that hemodynamic responsiveness to stressor tests in healthy subjects is positively influenced by male gender and family history of CVDs.     

Cardiovascular responses in Type A and Type B men to a series of stressors

Fifty-six healthy adult males were administered the Type A Structured Interview and assessed as exhibiting either Type A (N=42) or Type B (N=14) behavior pattern. They were monitored for systolic (SBP) and diastolic blood pressure (DBP) and heart rate (HR) responses during a series of six challenging tasks: Mental Arithmetic, Hypothesis Testing, Reaction Time, Video Game, Handgrip, and Cold Pressor. The results indicated that Type A subjects exhibited greater cardiovascular responses than did Type B subjects during some (Hypothesis Testing, Reaction Time, Video Game and Mental Arithmetic) but not all (Handgrip and Cold Pressor) of the tasks. These results are discussed in terms of previously reported findings on conditions that do and do not produce differences in Type A/B cardiovascular stress responses. This research was supported by USPHS Grant MH-31269. We would like to thank Drs. Steve Manuck, David Krantz, Ted Dembroski, Curt Sandman, David Hothersall, and Gifford Weary for their helpful comments on an earlier draft of this paper.     

Cardiac responses to pressor challenges in congenital central hypoventilation syndrome

Summary Question of the Study   Congenital central hypoventilation syndrome (CCHS) subjects exhibit diminished respiratory-related heart rate variation in addition to defining characteristics of CO₂ insensitivity and reduced ventilatory drive during sleep. Loss of cardiovascular and breathing coupling may diminish blood pressure influences on breathing; such influences may be determined by evaluating cardiorespiratory responses to different pressor challenges.
Patients and Methods   Ten children with CCHS and 10 age- and gender-matched controls were subjected to a forehead cold pressor challenge and to Valsalva maneuvers. Heart and respiratory rates and variability during 30-s baseline and 120-s challenge periods were assessed with scatterplot displays and by analysis of variance procedures.
Results   Cold pressor challenges enhanced breathing efforts and increased respiratory-related heart rate variation in controls but not in CCHS patients, while lower frequency heart rate variability increased in both controls and CCHS subjects. Heart rate variation resulting from voluntary expiratory efforts was present but slightly reduced in CCHS. Respiratory and cardiac rate trends differed in control and CCHS cases.
Conclusions   More-rapidly changing heart rate variation from spontaneous or reflexively-induced sources is diminished in CCHS but remains intact from voluntary expiratory ­efforts, as does slower variation. Loss of reflexive influences on breathing from blood pressure changes may attenuate a source of respiratory drive.     

Blood pressure and heart rate response to voluntary and non-voluntary static exercise in man

6 healthy men produced static knee extension with one leg for 5 min. In one series of experiments the force was held constant at 20% of the isometric maximum voluntary contraction force. In another series of experiments the same subjects performed the same work non-voluntarily by direct percutaneous electrical stimulation. Heart rate and blood pressure was continuously recorded. Heart rate increased by 40% and systolic and diastolic blood pressure by 30% and 50% in both kind of experiments. It is concluded that receptors within the muscle has the full capacity to adjust central circulation to the muscle work performed.     

Effect of arm-cranking on leg blood flow and noradrenaline spillover during leg exercise in man

Controversy exists whether recruitment of a large muscle mass in dynamic exercise may outstrip the pumping capacity of the heart and require neurogenic vasoconstriction in exercising muscle to prevent a fall in arterial blood pressure. To elucidate this question, seven healthy young men cycled for 70 minutes at a work load of 5540%VO_2max. At 30 to 50 minutes, arm cranking was added and total work load increased to (mean ± SE) 82 ± 4% of Vo_2max. During leg exercise, leg blood flow average 6.15 4.511 minutes^-1, mean arterial blood pressure 137 ± 4 mmHg and leg conductance 42.3 ± 2.2 ml minutes^-1 mmHg^-1. When arm cranking was added to leg cycling, leg blood flow did not change significantly, mean arterial blood pressure increased transiently to 147 ± 5 mmHg and leg vascular conductance decreased transiently to 33.5 ± 3.1 ml minutes^-1 mmHg^-1. Furthermore, arm cranking doubled leg noradrenaline spillover. When arm cranking was discontinued and leg cycling continued, leg blood flow was unchanged but mean arterial blood pressure decreased to values significantly below those measured in the first leg exercise period. Furthermore, leg vascular conductance increased transiently, and noradrenaline spillover decreased towards values measured during the first leg exercise period. It is concluded that addition of arm cranking to leg cycling increases leg noradrenaline spillover and decreases leg vascular conductance but leg blood flow remains unchanged because of a simultaneous increase in mean arterial blood pressure. The decrease in leg vascular conductance observed when arm cranking increased mean arterial blood pressure could be regarded more as a measure to prevent overperfusion than a measure to maintain arterial blood pressure.     

Cardiovascular responses during one- and two-legged exercise in middle-aged men

Eight healthy and regularly physically active men, 44–69 years old, performed one- and two-legged dynamic knee extension exercise at increasing work intensities, including one leading to exhaustion. Leg blood flow increased linearly in relation to work rate, reaching a peak value of 5.1 ±0.4 1 min^-1. With a mean weight of quadriceps femoris of 2.2 ±0.1 kg, a peak perfusion of 2.3 ±0.11 kg^-1 min^-1 was attained. The maximal leg oxygen uptake was 0.72 ±0.071 min^-1 (0.33 ±0.03 1 kg^-1 min^-1). At submaximal work the elevation in limb oxygen uptake accounted for between 70 and 100% of the rise in pulmonary oxygen uptake. Comparing two- with one-legged knee extension the cardiac output was 1.5 1 min^-1 higher at each work level, reaching 13.7±0.7 and 12.3 ± 1.0, respectively at exhaustion, leaving 3.5 and 7.2 1 min^-1 of blood flow to the remaining body (cardiac output –leg blood flow). The mean arterial pressure was 119 ±5 mmHg at rest and increased to 155 mmHg for both test modes at the maximal work rate. The femoral arterial and venous plasma concentrations of lactate, ammonia and noradrenaline were significantly higher for two-legged as compared with one-legged exercise at the maximal load performed. However, the rate of release per leg, for both lactate and ammonia, did not differ between the two test conditions. It is concluded that physically active middle-aged men, with a well-retained muscle mass, can maintain a high skeletal muscle perfusion, similar to that of young males. However, the blood flow is achieved with a higher mean arterial pressure and an elevated sympathetic activity, as reflected by noradrenaline in plasma and spillover from the exercising limb.     

Ageing reduces sympatho-suppressive response to head-out water immersion in humans

Muscle sympathetic nerve activity (MSNA) is suppressed during thermoneutral head-out water immersion (HOI) in humans. In this study, the effects of ageing on the suppressive response of MSNA to HOI were determined. MSNA was recorded microneurographically from the tibial nerve in 16 healthy men, 10 of whom were aged 19–30 years (young group) and six aged 45–67 years (older group). MSNA was suppressed in all the subjects during HOI. The suppressive response was significantly less prominent in the older group than in the young group. A significant negative correlation between age and the suppressive response of MSNA induced by HOI (r=-0.53, P<0.05) was found. We conclude that suppressive response of sympathetic nerve activity to HOI is reduced with age.     

Cardiovascular variability as a function of sleep–wake behaviour in narcolepsy with cataplexy

Hypocretin/orexin signalling varies among sleep–wake behaviours, impacts upon cardiovascular autonomic control and is impaired in patients with narcolepsy with cataplexy (NC). However, evidence concerning disturbed cardiovascular autonomic control in NC patients is contrasting, and limited mainly to waking behaviour. We thus investigated whether control of cardiovascular variability is altered in NC patients during wakefulness preceding sleep, light (1–2) and deep (3–4) stages of non‐rapid eye movement (NREM) sleep and rapid eye movement (REM) sleep. Polysomnographic recordings and finger blood pressure measurements were performed on nine drug‐free male NC patients and nine matched healthy control subjects during spontaneous sleep–wake behaviour in a standardized laboratory environment. Indices of autonomic function were computed based on spontaneous fluctuations of systolic blood pressure (SBP) and heart period (HP). During wakefulness before sleep, NC patients showed significant decreases in indices of vagal HP modulation, cardiac baroreflex sensitivity and amplitude of central autonomic (feed‐forward) cardiac control compared with control subjects. During NREM sleep, the negative correlation between HP and subsequent SBP values was greater in NC patients than in control subjects, suggesting a greater contribution of central autonomic commands to cardiac control. Collectively, these results provide preliminary evidence that autonomic control of cardiac variability by baroreflex and central autonomic (feed‐forward) mechanisms is altered in NC patients during spontaneous sleep–wake behaviour, and particularly during wakefulness before sleep.     

Temperature-induced changes in metabolic and hormonal responses to intensive dynamic exercise

Seven male subjects performed intensive cycle exercise to exhaustion at subnormal muscle temperature (T_m, 29 ± 2.8 °C). Exercise at exactly the same rate of exercise and duration (370 ± 34 W, 1.5 ± 0.15 min) was then repeated with normal T_m (35 ± 0.9 °C). During exercise both the arterial (a) and femoral venous (fv) contents of oxygen were significantly higher at subnormal than at normal T_m, because of the higher haemoglobin concentration, but the a-fv oxygen difference was the same in the two situations. The rate of increase in lactate concentration in both arterial and venous blood during exercise was the same in the two situations. During exercise the plasma concentrations of adrenaline and noradrealine in arterial and venous blood were significantly higher at subnormal than at normal T_m. At rest and after exercise the calf blood flow was significantly reduced at subnormal T_m At the end of exercise the concentrations of glucose-6-phosphate and lactate in the muscle were significantly higher at subnormal T_m than in the muscle of normal temperature. These findings suggest that there was a greater increase in glycolysis in the muscle of subnormal temperature during exercise, possibly as a result of impaired work efficiency and/or reduced blood flow in the cold muscle.     

Cardiovascular responses to a quantified dose of nicotine as a function of personality and nicotine tolerance

Correlations between cardiovascular effects of a quantified dose of nicotine and personality measures previously shown to predict coronary heart disease were obtained. Thirty male smokers smoked a popular brand of a regular strength cigarette (1.0 mg FTC-estimated nicotine delivery) on one occasion and a nicotine-free cigarette on another occasion by means of a quantified smoke delivery system. Partial correlations controlling for effects of body weight, questionnaire-assessed nicotine tolerance, and cardiovascular responses to the nicotine-free control cigarette showed Jenkins Activity Survey Type A scores to correlate positively with nicotine-induced increase in diastolic blood pressure but negatively with nicotine-induced increase in systolic blood pressure. Partial correlations indicated that trait anxiety and depression were significantly associated with nicotine-induced heart rate increases but not with nicotine-induced blood pressure responses.This work was supported by a grant from the Office of Research and Development Administration of Southern Illinois University at Carbondale. This article is based on the first author's thesis, which was supervised by the second author.     

Cardiovascular and behavioural responses to conditioned fear and restraint are not affected by retrograde lesions of A5 and C1 bulbospinal neurons

The aim of this study was to test a possible role of A5 neurons in the expression of the pressor and tachycardic responses to conditioned fear and restraint, two forms of psychological stress. Previous Fos studies have shown that the C1 adrenergic neurons and spinally projecting neurons in the vasopressor region of the rostral ventrolateral medulla are not activated by these two stressors, suggesting that these cardiovascular changes may be mediated by other premotor sympathetic (presympathetic) cell groups. The same studies also revealed that the A5 noradrenergic group was one of the main presympathetic cell groups to be activated in response to these two stressors. Thus, we hypothesized that the A5 group could mediate these cardiovascular responses. Conditioned fear and restraint were tested in rats implanted with radiotelemetric probes before and after retrograde lesion with the selective toxin anti-dopamine-β-hydroxylase-saporin bilaterally injected in the spinal cord at T2–T3. Six animals were selected that had the most extensive loss of spinally projecting catecholaminergic neurons: A5 (81%–95%) and rostral C1 (59%–86%, which would include most C1 bulbospinal neurons). However, despite this major loss of noradrenergic and adrenergic presympathetic neurons, the magnitude of the cardiovascular response to conditioned fear and restraint was the same before and after the lesion. Associated behavioural changes were not affected either. The results indicate that A5 presympathetic neurons are not essential for the expression of the tachycardic and pressor responses to conditioned fear and restraint. They also confirm that C1 bulbospinal neurons are not involved in these responses. The presympathetic neurons driving the tachycardic and pressor responses to conditioned fear and restraint must be elsewhere.     

Cardiovascular responses and the sense of effort during attempts to contract paralysed muscles: role of the spinal cord

To determine whether spinal transection affects the cardiovascular response and the sense of effort which accompany attempts to contract paralysed muscles in normal subjects, paraplegic patients tried to contract paralysed leg muscles. During attempted contractions, paraplegic subjects reported a sense of effort but did not change heart rate or blood pressure. However, these subjects had a normal cardiovascular response to handgrip contractions. These data suggest that pathways descending to and arising from the spinal cord below the lesion are required to generate a cardiovascular response but are not necessary for the sense of effort.     

Contribution of systemic arterial compliance and systemic vascular resistance to effective arterial elastance changes during exercise in humans

Background: Effective arterial elastance (Ea), an index of arterial load, increases with elevations in left ventricular elastance to maximize the efficiency of left ventricular stroke work during exercise. Systemic arterial compliance (C) and vascular resistance (R) are the primary components contributing to Ea, and R plays a greater role in determining Ea at rest. We hypothesized that the contribution of C to Ea increases during exercise to maintain an optimal balance between arterial load and ventricular elastance, and that the increase in Ea is due primarily to a reduction in C. Aim: The aim of this study was to investigate the contributions of C and R to Ea during exercise. Methods: Ea (0.9 × systolic blood pressure/stroke volume), C (stroke volume/pulse pressure), R (mean blood pressure/cardiac output), and cardiac cycle length (T) were measured at rest and during exercise of 40%, 60% and 80% maximal oxygen uptake (O_2max) using Doppler echocardiography in 45 healthy men. Results: Ea did not differ between rest and 40%O_2max, but it was greater at 60% and 80%O_2max. C markedly decreased during exercise in an exercise intensity‐dependent manner. The changes in R/T during exercise were small, whereas it decreased at 40%O_2max and gradually increased at 60% and 80%O_2max. Conclusions: The present results suggest that the contribution of systemic arterial compliance to effective arterial elastance increases during exercise. Therefore, we propose that the increase in arterial load during exercise is mainly driven by a reduction in systemic arterial compliance.